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source: src/SymTab/Mangler.cc @ ee27df2

ADTaaron-thesisarm-ehast-experimentalcleanup-dtorsdeferred_resnenumforall-pointer-decayjacob/cs343-translationjenkins-sandboxnew-astnew-ast-unique-exprno_listpersistent-indexerpthread-emulationqualifiedEnum

Last change on this file since ee27df2 was 0e761e40, checked in by Rob Schluntz <rschlunt@…>, 6 years ago
Change type variable name mangling to use combination of tyvar position/encoding prefix rather than type variable name
Property mode set to `100644`
File size: 15.4 KB

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1	//
2	// Cforall Version 1.0.0 Copyright (C) 2015 University of Waterloo
3	//
4	// The contents of this file are covered under the licence agreement in the
5	// file "LICENCE" distributed with Cforall.
6	//
7	// Mangler.cc --
8	//
9	// Author : Richard C. Bilson
10	// Created On : Sun May 17 21:40:29 2015
11	// Last Modified By : Peter A. Buhr
12	// Last Modified On : Mon Sep 25 15:49:26 2017
13	// Update Count : 23
14	//
15	#include "Mangler.h"
16
17	#include <algorithm> // for copy, transform
18	#include <cassert> // for assert, assertf
19	#include <functional> // for const_mem_fun_t, mem_fun
20	#include <iterator> // for ostream_iterator, back_insert_ite...
21	#include <list> // for _List_iterator, list, _List_const...
22	#include <string> // for string, char_traits, operator<<
23
24	#include "CodeGen/OperatorTable.h" // for OperatorInfo, operatorLookup
25	#include "Common/PassVisitor.h"
26	#include "Common/SemanticError.h" // for SemanticError
27	#include "Common/utility.h" // for toString
28	#include "Parser/LinkageSpec.h" // for Spec, isOverridable, AutoGen, Int...
29	#include "SynTree/Declaration.h" // for TypeDecl, DeclarationWithType
30	#include "SynTree/Expression.h" // for TypeExpr, Expression, operator<<
31	#include "SynTree/Type.h" // for Type, ReferenceToType, Type::Fora...
32
33	namespace SymTab {
34	namespace Mangler {
35	namespace {
36	/// Mangles names to a unique C identifier
37	struct Mangler : public WithShortCircuiting, public WithVisitorRef<Mangler>, public WithGuards {
38	Mangler( bool mangleOverridable, bool typeMode, bool mangleGenericParams );
39	Mangler( const Mangler & ) = delete;
40
41	void previsit( BaseSyntaxNode * ) { visit_children = false; }
42
43	void postvisit( ObjectDecl * declaration );
44	void postvisit( FunctionDecl * declaration );
45	void postvisit( TypeDecl * declaration );
46
47	void postvisit( VoidType * voidType );
48	void postvisit( BasicType * basicType );
49	void postvisit( PointerType * pointerType );
50	void postvisit( ArrayType * arrayType );
51	void postvisit( ReferenceType * refType );
52	void postvisit( FunctionType * functionType );
53	void postvisit( StructInstType * aggregateUseType );
54	void postvisit( UnionInstType * aggregateUseType );
55	void postvisit( EnumInstType * aggregateUseType );
56	void postvisit( TypeInstType * aggregateUseType );
57	void postvisit( TraitInstType * inst );
58	void postvisit( TupleType * tupleType );
59	void postvisit( VarArgsType * varArgsType );
60	void postvisit( ZeroType * zeroType );
61	void postvisit( OneType * oneType );
62	void postvisit( QualifiedType * qualType );
63
64	std::string get_mangleName() { return mangleName.str(); }
65	private:
66	std::ostringstream mangleName; ///< Mangled name being constructed
67	typedef std::map< std::string, std::pair< int, int > > VarMapType;
68	VarMapType varNums; ///< Map of type variables to indices
69	int nextVarNum; ///< Next type variable index
70	bool isTopLevel; ///< Is the Mangler at the top level
71	bool mangleOverridable; ///< Specially mangle overridable built-in methods
72	bool typeMode; ///< Produce a unique mangled name for a type
73	bool mangleGenericParams; ///< Include generic parameters in name mangling if true
74	bool inFunctionType = false; ///< Include type qualifiers if false.
75	bool inQualifiedType = false; ///< Add start/end delimiters around qualified type
76
77	void mangleDecl( DeclarationWithType *declaration );
78	void mangleRef( ReferenceToType *refType, std::string prefix );
79
80	void printQualifiers( Type *type );
81	}; // Mangler
82	} // namespace
83
84	std::string mangle( BaseSyntaxNode * decl, bool mangleOverridable, bool typeMode, bool mangleGenericParams ) {
85	PassVisitor<Mangler> mangler( mangleOverridable, typeMode, mangleGenericParams );
86	maybeAccept( decl, mangler );
87	return mangler.pass.get_mangleName();
88	}
89
90	std::string mangleType( Type * ty ) {
91	PassVisitor<Mangler> mangler( false, true, true );
92	maybeAccept( ty, mangler );
93	return mangler.pass.get_mangleName();
94	}
95
96	std::string mangleConcrete( Type * ty ) {
97	PassVisitor<Mangler> mangler( false, false, false );
98	maybeAccept( ty, mangler );
99	return mangler.pass.get_mangleName();
100	}
101
102	namespace {
103	Mangler::Mangler( bool mangleOverridable, bool typeMode, bool mangleGenericParams )
104	: nextVarNum( 0 ), isTopLevel( true ), mangleOverridable( mangleOverridable ), typeMode( typeMode ), mangleGenericParams( mangleGenericParams ) {}
105
106	void Mangler::mangleDecl( DeclarationWithType * declaration ) {
107	bool wasTopLevel = isTopLevel;
108	if ( isTopLevel ) {
109	varNums.clear();
110	nextVarNum = 0;
111	isTopLevel = false;
112	} // if
113	mangleName << Encoding::manglePrefix;
114	CodeGen::OperatorInfo opInfo;
115	if ( operatorLookup( declaration->get_name(), opInfo ) ) {
116	mangleName << opInfo.outputName.size() << opInfo.outputName;
117	} else {
118	mangleName << declaration->name.size() << declaration->name;
119	} // if
120	maybeAccept( declaration->get_type(), *visitor );
121	if ( mangleOverridable && LinkageSpec::isOverridable( declaration->get_linkage() ) ) {
122	// want to be able to override autogenerated and intrinsic routines,
123	// so they need a different name mangling
124	if ( declaration->get_linkage() == LinkageSpec::AutoGen ) {
125	mangleName << Encoding::autogen;
126	} else if ( declaration->get_linkage() == LinkageSpec::Intrinsic ) {
127	mangleName << Encoding::intrinsic;
128	} else {
129	// if we add another kind of overridable function, this has to change
130	assert( false && "unknown overrideable linkage" );
131	} // if
132	}
133	isTopLevel = wasTopLevel;
134	}
135
136	void Mangler::postvisit( ObjectDecl * declaration ) {
137	mangleDecl( declaration );
138	}
139
140	void Mangler::postvisit( FunctionDecl * declaration ) {
141	mangleDecl( declaration );
142	}
143
144	void Mangler::postvisit( VoidType * voidType ) {
145	printQualifiers( voidType );
146	mangleName << Encoding::void_t;
147	}
148
149	void Mangler::postvisit( BasicType * basicType ) {
150	printQualifiers( basicType );
151	assertf( basicType->get_kind() < BasicType::NUMBER_OF_BASIC_TYPES, "Unhandled basic type: %d", basicType->get_kind() );
152	mangleName << Encoding::basicTypes[ basicType->get_kind() ];
153	}
154
155	void Mangler::postvisit( PointerType * pointerType ) {
156	printQualifiers( pointerType );
157	// mangle void (*f)() and void f() to the same name to prevent overloading on functions and function pointers
158	if ( ! dynamic_cast<FunctionType *>( pointerType->base ) ) mangleName << Encoding::pointer;
159	maybeAccept( pointerType->base, *visitor );
160	}
161
162	void Mangler::postvisit( ArrayType * arrayType ) {
163	// TODO: encode dimension
164	printQualifiers( arrayType );
165	mangleName << Encoding::array << "0";
166	maybeAccept( arrayType->base, *visitor );
167	}
168
169	void Mangler::postvisit( ReferenceType * refType ) {
170	// don't print prefix (e.g. 'R') for reference types so that references and non-references do not overload.
171	// Further, do not print the qualifiers for a reference type (but do run printQualifers because of TypeDecls, etc.),
172	// by pretending every reference type is a function parameter.
173	GuardValue( inFunctionType );
174	inFunctionType = true;
175	printQualifiers( refType );
176	maybeAccept( refType->base, *visitor );
177	}
178
179	namespace {
180	inline std::list< Type* > getTypes( const std::list< DeclarationWithType* > decls ) {
181	std::list< Type* > ret;
182	std::transform( decls.begin(), decls.end(), std::back_inserter( ret ),
183	std::mem_fun( &DeclarationWithType::get_type ) );
184	return ret;
185	}
186	}
187
188	void Mangler::postvisit( FunctionType * functionType ) {
189	printQualifiers( functionType );
190	mangleName << Encoding::function;
191	// turn on inFunctionType so that printQualifiers does not print most qualifiers for function parameters,
192	// since qualifiers on outermost parameter type do not differentiate function types, e.g.,
193	// void ()(const int) and void ()(int) are the same type, but void ()(const int ) and void ()(int ) are different
194	GuardValue( inFunctionType );
195	inFunctionType = true;
196	std::list< Type* > returnTypes = getTypes( functionType->returnVals );
197	if (returnTypes.empty()) mangleName << Encoding::void_t;
198	else acceptAll( returnTypes, *visitor );
199	mangleName << "_";
200	std::list< Type* > paramTypes = getTypes( functionType->parameters );
201	acceptAll( paramTypes, *visitor );
202	mangleName << "_";
203	}
204
205	void Mangler::mangleRef( ReferenceToType * refType, std::string prefix ) {
206	printQualifiers( refType );
207
208	mangleName << prefix << refType->name.length() << refType->name;
209
210	if ( mangleGenericParams ) {
211	std::list< Expression* >& params = refType->parameters;
212	if ( ! params.empty() ) {
213	mangleName << "_";
214	for ( std::list< Expression* >::const_iterator param = params.begin(); param != params.end(); ++param ) {
215	TypeExpr paramType = dynamic_cast< TypeExpr >( *param );
216	assertf(paramType, "Aggregate parameters should be type expressions: %s", toCString(*param));
217	maybeAccept( paramType->type, *visitor );
218	}
219	mangleName << "_";
220	}
221	}
222	}
223
224	void Mangler::postvisit( StructInstType * aggregateUseType ) {
225	mangleRef( aggregateUseType, Encoding::struct_t );
226	}
227
228	void Mangler::postvisit( UnionInstType * aggregateUseType ) {
229	mangleRef( aggregateUseType, Encoding::union_t );
230	}
231
232	void Mangler::postvisit( EnumInstType * aggregateUseType ) {
233	mangleRef( aggregateUseType, Encoding::enum_t );
234	}
235
236	void Mangler::postvisit( TypeInstType * typeInst ) {
237	VarMapType::iterator varNum = varNums.find( typeInst->get_name() );
238	if ( varNum == varNums.end() ) {
239	mangleRef( typeInst, Encoding::type );
240	} else {
241	printQualifiers( typeInst );
242	// Note: Can't use name here, since type variable names do not actually disambiguate a function, e.g.
243	// forall(dtype T) void f(T);
244	// forall(dtype S) void f(S);
245	// are equivalent and should mangle the same way. This is accomplished by numbering the type variables when they
246	// are first found and prefixing with the appropriate encoding for the type class.
247	assertf( varNum->second.second < TypeDecl::NUMBER_OF_KINDS, "Unhandled type variable kind: %d", varNum->second.second );
248	mangleName << Encoding::typeVariables[varNum->second.second] << varNum->second.first;
249	} // if
250	}
251
252	void Mangler::postvisit( TraitInstType * inst ) {
253	printQualifiers( inst );
254	mangleName << inst->name.size() << inst->name;
255	}
256
257	void Mangler::postvisit( TupleType * tupleType ) {
258	printQualifiers( tupleType );
259	mangleName << Encoding::tuple << tupleType->types.size();
260	acceptAll( tupleType->types, *visitor );
261	}
262
263	void Mangler::postvisit( VarArgsType * varArgsType ) {
264	printQualifiers( varArgsType );
265	static const std::string vargs = "__builtin_va_list";
266	mangleName << Encoding::type << vargs.size() << vargs;
267	}
268
269	void Mangler::postvisit( ZeroType * ) {
270	mangleName << Encoding::zero;
271	}
272
273	void Mangler::postvisit( OneType * ) {
274	mangleName << Encoding::one;
275	}
276
277	void Mangler::postvisit( QualifiedType * qualType ) {
278	bool inqual = inQualifiedType;
279	if (! inqual ) {
280	// N marks the start of a qualified type
281	inQualifiedType = true;
282	mangleName << Encoding::qualifiedTypeStart;
283	}
284	maybeAccept( qualType->parent, *visitor );
285	maybeAccept( qualType->child, *visitor );
286	if ( ! inqual ) {
287	// E marks the end of a qualified type
288	inQualifiedType = false;
289	mangleName << Encoding::qualifiedTypeEnd;
290	}
291	}
292
293	void Mangler::postvisit( TypeDecl * decl ) {
294	// TODO: is there any case where mangling a TypeDecl makes sense? If so, this code needs to be
295	// fixed to ensure that two TypeDecls mangle to the same name when they are the same type and vice versa.
296	// Note: The current scheme may already work correctly for this case, I have not thought about this deeply
297	// and the case has not yet come up in practice. Alternatively, if not then this code can be removed
298	// aside from the assert false.
299	assertf(false, "Mangler should not visit typedecl: %s", toCString(decl));
300	assertf( decl->get_kind() < TypeDecl::NUMBER_OF_KINDS, "Unhandled type variable kind: %d", decl->get_kind() );
301	mangleName << Encoding::typeVariables[ decl->get_kind() ] << ( decl->name.length() ) << decl->name;
302	}
303
304	__attribute__((unused)) void printVarMap( const std::map< std::string, std::pair< int, int > > &varMap, std::ostream &os ) {
305	for ( std::map< std::string, std::pair< int, int > >::const_iterator i = varMap.begin(); i != varMap.end(); ++i ) {
306	os << i->first << "(" << i->second.first << "/" << i->second.second << ")" << std::endl;
307	} // for
308	}
309
310	void Mangler::printQualifiers( Type * type ) {
311	// skip if not including qualifiers
312	if ( typeMode ) return;
313	if ( ! type->get_forall().empty() ) {
314	std::list< std::string > assertionNames;
315	int dcount = 0, fcount = 0, vcount = 0, acount = 0;
316	mangleName << Encoding::forall;
317	for ( Type::ForallList::iterator i = type->forall.begin(); i != type->forall.end(); ++i ) {
318	switch ( (*i)->get_kind() ) {
319	case TypeDecl::Dtype:
320	dcount++;
321	break;
322	case TypeDecl::Ftype:
323	fcount++;
324	break;
325	case TypeDecl::Ttype:
326	vcount++;
327	break;
328	default:
329	assert( false );
330	} // switch
331	varNums[ (i)->name ] = std::pair< int, int >( nextVarNum++, (int)(i)->get_kind() );
332	for ( std::list< DeclarationWithType* >::iterator assert = (i)->assertions.begin(); assert != (i)->assertions.end(); ++assert ) {
333	PassVisitor<Mangler> sub_mangler( mangleOverridable, typeMode, mangleGenericParams );
334	sub_mangler.pass.nextVarNum = nextVarNum;
335	sub_mangler.pass.isTopLevel = false;
336	sub_mangler.pass.varNums = varNums;
337	(*assert)->accept( sub_mangler );
338	assertionNames.push_back( sub_mangler.pass.mangleName.str() );
339	acount++;
340	} // for
341	} // for
342	mangleName << dcount << "_" << fcount << "_" << vcount << "_" << acount << "_";
343	std::copy( assertionNames.begin(), assertionNames.end(), std::ostream_iterator< std::string >( mangleName, "" ) );
344	mangleName << "_";
345	} // if
346	if ( ! inFunctionType ) {
347	// these qualifiers do not distinguish the outermost type of a function parameter
348	if ( type->get_const() ) {
349	mangleName << Encoding::qualifiers.at(Type::Const);
350	} // if
351	if ( type->get_volatile() ) {
352	mangleName << Encoding::qualifiers.at(Type::Volatile);
353	} // if
354	// Removed due to restrict not affecting function compatibility in GCC
355	// if ( type->get_isRestrict() ) {
356	// mangleName << "E";
357	// } // if
358	if ( type->get_atomic() ) {
359	mangleName << Encoding::qualifiers.at(Type::Atomic);
360	} // if
361	}
362	if ( type->get_mutex() ) {
363	mangleName << Encoding::qualifiers.at(Type::Mutex);
364	} // if
365	if ( type->get_lvalue() ) {
366	// mangle based on whether the type is lvalue, so that the resolver can differentiate lvalues and rvalues
367	mangleName << Encoding::qualifiers.at(Type::Lvalue);
368	}
369
370	if ( inFunctionType ) {
371	// turn off inFunctionType so that types can be differentiated for nested qualifiers
372	GuardValue( inFunctionType );
373	inFunctionType = false;
374	}
375	}
376	} // namespace
377	} // namespace Mangler
378	} // namespace SymTab
379
380	// Local Variables: //
381	// tab-width: 4 //
382	// mode: c++ //
383	// compile-command: "make install" //
384	// End: //

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